A phase change memory includes an L-shaped resistive element having a first part that extends between a layer of phase change material and an upper end of a conductive via and a second part that rests at least partially on the upper end of the conductive via and may further extend beyond a peripheral edge of the conductive via. The upper part of the conductive via is surrounded by an insulating material that is not likely to adversely react with the metal material of the resistive element.
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1. A method, comprising:
depositing a first insulating layer made of a first insulating material on a second insulating layer made of a second insulating material;
forming a conductive via traversing through the first and second insulating layers;
depositing a third insulating layer made of the first insulating material on the first insulating layer and upper end of the conductive via;
forming a cavity that passes through the third insulating layer and that at least partially reveals the upper end of the conductive via;
depositing a layer of a resistive material on side walls and a bottom of the cavity and in contact with the upper end of the conductive via, wherein the first insulating material does not react with the resistive material;
forming a first spacer on the layer of the resistive material in the cavity;
etching away a portion of the layer of resistive material that is not protected by the first spacer;
forming a second spacer on a side of the first spacer and which at least partially covers an end of the layer of resistive material exposed by said etching away;
filling the cavity with a fourth insulating layer made of an insulating material; and
depositing a layer of phase change material on the fourth insulating layer and in contact with an upper end of the layer of resistive material in the cavity.
17. A method, comprising:
depositing a first insulating layer over an integrated circuit transistor;
forming a conductive via traversing through the first insulating layer to electrically connect with the integrated circuit transistor;
depositing a second insulating layer on the first insulating layer and upper end of the conductive via;
forming a cavity that passes through the second insulating layer and that at least partially reveals the upper end of the conductive via;
depositing a layer of a resistive material on side walls and a bottom of the cavity and in contact with the upper end of the conductive via, wherein the resistive material is made of a material which does oxidize in response to contact with a material of the first and second insulating layers;
forming a first spacer at sidewalls of the cavity, the first spacer in contact with the layer of the resistive material;
etching away a portion of the layer of resistive material that is not protected by the first spacer;
forming a second spacer on a sidewall of the first spacer and which at least partially covers an end of the layer of resistive material exposed by said etching away;
filling the cavity with an insulating oxide material, the first and second spacers protecting the layer of resistive material from being oxidized; and
depositing a layer of phase change material on the insulating oxide material and in contact with an upper end of the layer of resistive material in the cavity.
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This application is a divisional from United States Applications for patent Ser. No. 15/953,921 filed Apr. 16, 2018, which claims the priority benefit of French Application for Patent No. 1753345, filed on Apr. 18, 2017, the disclosures of which are hereby incorporated by reference in their entireties to the maximum extent allowable by law.
The present application relates to an electronic circuit, and more particularly to Phase Change Memory (PCM).
A phase change material may switch, under the effect of heat, between a crystalline phase and an amorphous phase. As the electrical resistance of an amorphous material is significantly greater than the electrical resistance of a crystalline material, it is possible to determine two memorizable states (e.g., 0 and 1) of the phase change material differentiated by the measured resistance.
In an embodiment, a phase change memory includes an L-shaped resistive element, wherein a first part of the resistive element extends between a layer of phase change material and the upper end of a conductive via, and a second part of the resistive element rests at least partially on the upper end of the conductive via, the upper part of the conductive via being surrounded by an insulator not likely to react with the resistive element.
According to one embodiment, the insulator is silicon nitride.
According to one embodiment, the phase change material is an alloy including germanium, antimony and tellurium.
According to one embodiment, the conductive via has a diameter of less than 35 nm.
According to one embodiment, the resistive element is made of titanium nitride.
In an embodiment, a method for manufacturing phase change memory includes: depositing a first layer of a first insulator on a second insulator; forming conductive vias traversing the layer of first insulator and the second insulator; depositing a second layer of the first insulator; forming a cavity in the second layer of first insulator that extends from one via to the other and at least partially reveals the upper end of each of the vias; depositing a layer of resistive material, wherein the first insulator is not likely to react with the resistive material; forming first spacers in the first insulator on the flanks of the cavity; etching the resistive material not protected by the first spacers; forming second spacers in the first insulator on the flanks of the cavity; filling the second insulator cavity; and depositing a layer of phase change material.
According to one embodiment, the first insulator is silicon nitride.
According to one embodiment, the second insulator is silicon oxide.
According to one embodiment, the thickness of the first layer of first insulator is between 10 and 30 nm.
According to one embodiment, the thickness of the layer of resistive material is between 3 and 6 nm.
According to one embodiment, the resistive material is titanium nitride.
These features and advantages, as well as others, will be disclosed in detail in the following non-restrictive description of particular embodiments in relation to the accompanying figures in which:
The same elements have been designated by the same references in the different figures and, in addition, the various figures are not drawn to scale. For the sake of clarity, only the elements useful to the understanding of the embodiments described have been represented and are given in detail. In particular, the different etching masks are neither described nor represented.
In the description that follows, when reference is made to terms such as “upper”, “vertical”, “horizontal”, “left” or “right”, etc., it refers to the orientation of the figures. The term “vertical” is to be understood as within 10 degrees. Unless otherwise specified, the expression “substantially” means within 10%, preferably within 5%.
Two conductive vias 21 traverse the layer 20 of silicon oxide and the layer 18 of silicon nitride. Each via 21 reaches the layer 16 of silicide covering a drain/source area. Each via 21 is sheathed with a layer 22 of conductive protection (e.g. made of Ti/TiN) and comprises a conductive core 24 (e.g. made of tungsten).
The layer 20 of silicon oxide and the conductive vias 21 are covered with a layer 26 of silicon nitride, in which a cavity 27 is etched. The cavity 27 extends from one conductive via 21 to an adjacent conductive via and at least partially reveals the upper end of the two adjacent conductive vias 21. L-shaped resistive elements 28 are formed on the flanks of this cavity. One part (or leg), substantially vertical, of each L-shaped resistive element 28 extends along the layer 26 of silicon nitride and another, horizontal, part (or leg) of the L-shaped resistive element extends over the upper end of a conductive via 21. The resistive elements 28, with the exception of their upper ends, are covered with spacers 30 (e.g. made of silicon nitride). The rest of the cavity is filled with an insulator 31 (e.g. silicon oxide).
The whole of the structure described so far is covered with a layer 32 of phase change material (e.g. an alloy including germanium, antimony and tellurium). The layer 32 is in contact with the upper end of each resistive element 28. The layer 32 is covered with a layer 34 of conductive material, a layer 36 of insulator (e.g. silicon nitride) and a layer 38 of insulator (e.g. silicon oxide).
A via 42 traverses the layers of insulators 36 and 38 so as to make contact with the layer 34 of conductive material. The via 42 is sheathed with a layer 22 of conductive protection (e.g. made of Ti/TiN) and comprises a conductive core (e.g. made of tungsten).
When writing to a phase change memory element, a current is sent between a via 21 and the conductive layer 34 to the via 42. The intensity of this current is chosen so as to increase the temperature of the resistive element 28 sufficiently to make an area 43 of the layer 32 of phase change material in contact with the upper end of the resistive element 28 switch from the weakly resistive crystalline phase to the highly resistive amorphous phase. It is assumed, for example, that the crystalline phase corresponds to the value 0 and the amorphous phase corresponds to the value 1.
When reading from a phase change memory, a current, having a sufficiently low intensity not to lead to phase change, is sent between the vias 21 and 42 so as to measure the resistance between them and therefore to determine the value, 0 or 1, stored in memory.
The position of the resistive elements 28 is determined by the position of a mask used for delimiting the etching of the cavity 27. This mask has to be aligned with the masks used previously, notably for defining the vias 21, but alignment errors may occur the value of which may range, for example, up to 20 nm. For a via 21 having, for example, a diameter equal to 150 nm, such an error does not pose a problem. However, in the case of a via 21 having, for example, a diameter of less than 35 nm (e.g. between 25 and 35 nm) it is possible to obtain a situation such as that illustrated in
The resistive element 28-1 is shifted to the right in the direction of the other via 21. The horizontal part of the resistive element 28-1 then extends partially over the via 21 and includes a part that extends past the peripheral edge of the via and partially over and in contact with the layer 20 of silicon oxide.
The resistive element 28-2 is also shifted to the right. Thus, the area where the horizontal and vertical parts of the resistive element 28-2 meet is located in the layer 20 of silicon oxide.
The two resistive elements are therefore in contact with the silicon oxide which may lead to oxidation of the elements 28-1 and 28-2 and a variation in their short-term or long-term resistances. This oxidation may cause an increase in the resistivity of the elements 28-1 and 28-2, which could, for example, no longer be able to reach the temperature required for the phase change and therefore for storage in memory.
This problem may also arise in a case where the mask is perfectly aligned. Indeed, the horizontal parts of the resistive elements 28-1 and 28-2 are rectangular in shape and the conductive vias 21 are, for example, circular in shape. Reducing the diameter of the vias 21 may therefore lead to the resistive elements overrunning at the corners. For example, for vias having a diameter of less than 35 nm (e.g. between 25 and 35 nm) and for resistive elements the horizontal part of which has dimensions of 25 nm by 50 nm, there will be overflow of the resistive elements 28-1 and 28-2 onto the silicon oxide 20 regardless of the mask's alignment.
In the case described in relation to
It would be desirable to provide phase change memory the resistive element of which is protected against oxidation.
By way of example, the resistive elements 28-1 and 28-2, with the exception of their lower part in contact with the via 21 and their upper end in contact with the phase change material, are completely surrounded by silicon nitride 26, 30 and 45 and are nowhere in contact with a material likely to react with them such as silicon oxide which is likely to oxidize them. The parts of the resistive elements 28 that extend out past the peripheral edge of the via 21 are insulated from the oxide material by the nitride material.
In the step illustrated in
A layer 46 of silicon nitride is then formed on the layer 20 of silicon oxide of the initial structure. The layer 46 has a thickness of between 10 and 30 nm (e.g. 20 nm). Portions of this layer 46 will correspond to the areas 45 illustrated in
In the step illustrated in
In the step illustrated in
In the step the result of which is illustrated in
A layer of resistive material (e.g. made of titanium nitride and of a thickness between 3 and 6 nm) is deposited on the structure. Spacers 54 (e.g. made of silicon nitride) are formed on the flanks of the cavity 53. The resistive material not protected by the spacers 54 is etched, thus forming L-shaped resistive elements 28. The ends of the vertical and horizontal parts of each resistive element 28, corresponding to the etching limits, are not covered by the spacers 54.
The parts of the resistive elements that overflow on one side or the other of the vias 21 and which were in contact with silicon oxide in the example in
In the step the result of which is illustrated in
In the step illustrated in
The layer 32 of phase change material is then covered with a layer 34 of conductive material, a layer 36 of insulator (e.g. silicon nitride) and a layer 38 of insulator (e.g. silicon oxide).
A via 42 is formed across the layers of insulators 36 and 38 so as to make contact with the layer 34 of conductive material. The via 42 is sheathed with a layer 22 of conductive protection (e.g. made of Ti/TiN) and comprises a conductive core (e.g. made of tungsten).
Reading from and writing to the memory elements take place as has been described in relation to
One advantage of this embodiment is that it only adds a few steps to the usual method and notably no additional masking step.
Particular embodiments have been described. Various variants and modifications will be apparent to the person skilled in the art. In particular, the selector transistors are not limited to the type of transistors described. In addition, the different materials may be replaced by equivalent materials, in particular, the silicon nitride of the layer 46 may be replaced by any other insulator not likely to react with the resistive elements 28.
Zuliani, Paola, Haond, Michel, Morin, Pierre
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